%0 Journal Article %J Energy and Buildings %D 2016 %T Balancing daylight, glare, and energy-efficiency goals: An evaluation of exterior coplanar shading systems using complex fenestration modeling tools %A Sabine Hoffmann %A Eleanor S. Lee %A Andrew McNeil %A Luis L. Fernandes %A Dragan Vidanovic %A Anothai Thanachareonkit %K Complex fenestration systems %K Discomfort Glare %K Energy Plus %K Energy Use Intensity %K Exterior shades %K Glare Control %K radiance %X

Exterior shades are the most effective way to control solar load in buildings. Twelve different coplanar shades with different geometry, material properties and cut-off angles were investigated for two California climates: the moderate San Francisco Bay Area climate and a hot and dry Southern California climate. The presented results distinguish themselves from other simulation studies by a newly developed method that combines three research-grade software programs (Radiance, EnergyPlus and Window 7) to calculate heat transfer, daylight, and glare resulting from optically-complex fenestration systems more accurately. Simulations were run for a case with constant electric lighting and a case with daylighting controls for a prototypical, internal load dominated office building.

In the case of daylighting controls, the choice of slat angle and solar cut-off angle of a fixed exterior slat shading system is non trivial. An optimum slat angle was identified for the considered cases. Material properties (e.g., solar and visible reflectance) did not affect energy use if constant electric lighting was assumed, but they did have a significant influence on energy use intensity (EUI) when daylighting controls were assumed. Energy use increased substantially when an additional interior shade was used for glare control.

%B Energy and Buildings %V 112 %P 279-298 %8 01/2016 %2 LBNL-1005092 %R 10.1016/j.enbuild.2015.12.009 %0 Conference Proceedings %B 10th International Conference on Advanced Building Skins %D 2015 %T Discomfort glare with complex fenestration systems and the impact on energy use when using daylighting control %A Sabine Hoffmann %A Andrew McNeil %A Eleanor S. Lee %A Raghuram Kalyanam %K building simulation %K Complex fenestration systems %K daylighting control %K Discomfort Glare %K Energy Use Intensity %K radiance %B 10th International Conference on Advanced Building Skins %C Bern, Switzerland %8 11/2015 %2 LBNL-1005094 %0 Conference Paper %B Fourth BEST Conference Building Enclosure Science & Technology (BEST4) %D 2015 %T Potential energy savings with exterior shades in large office buildings and the impact of discomfort glare %A Sabine Hoffmann %A Eleanor S. Lee %X

Exterior shades are highly efficient for reducing solar load in commercial buildings. Their impact on net energy use depends on the annual energy balance of heating, cooling, fan and lighting energy. This paper discusses the overall energy use intensity of various external shading systems for a prototypical large office building split into the different types of energy use and for different orientations and window sizes. Lighting energy was calculated for a constant lighting power as well as for dimmed lighting fixtures (daylighting control).

In Section 3, slat angles and solar cut-off angles were varied for fixed exterior slat shading systems. While the most light-blocking shades performed best for the case without daylighting controls, the optimum cut-off angle with daylighting controls was found to be 30 deg for the office building prototype used in Chicago and Houston. For large window-to-wall (WWR) ratios, window related annual energy use could be reduced by at least 70 % without daylighting control and by a minimum of 86 % with daylighting control in average over all orientations.

The occurrence of discomfort glare was is considered in Section 4 of the paper, which looks at the performance of commercially available exterior shading systems when an interior shade is used in addition to the exterior shade during hours when occupants would experience discomfort glare. Glare control impacts overall energy use intensity significantly for exterior shades with high transmittance, especially when daylighting controls are used. In these cases, exterior shades are only beneficial for window-to-wall areas ≥ 45% in the hot Houston climate. For smaller windows and in a heating/cooling climate like Chicago, exterior shades can increase energy consumption.

%B Fourth BEST Conference Building Enclosure Science & Technology (BEST4) %C Kansas City, Missouri %8 04/2015 %2 LBNL-187170 %0 Report %D 2014 %T Angular selective window systems: Assessment of technical potential for energy saving %A Luis L. Fernandes %A Eleanor S. Lee %A Andrew McNeil %A Jacob C. Jonsson %A Thierry Stephane Nouidui %A Xiufeng Pang %A Sabine Hoffmann %K angular selective systems %K Building energy-efficiency %K daylighting %K Shading Systems %K windows %X

Static angular selective shading systems block or filter direct sunlight and admit daylight within a specific range of incident solar angles. They can potentially deliver energy efficient performance within the typical 4.6-m (15-ft) deep perimeter zone of buildings when tailored to a specific façade orientation and latitude. The objective of this study is to quantify the technical potential of these systems to reduce energy use and peak demand in commercial buildings, specifically: a) achieve 30-50% reductions in perimeter zone energy use vs. ASHRAE 90.1-2004, b) constrain peak window loads to less than 43 W/m2-floor (4 W/ft2-floor), and c) to the extent possible, admit useful daylight in the perimeter zone without exceeding the peak solar load constraint. Three distinctly different commercial shading systems were evaluated: a micro-perforated screen, a tubular shading structure (double- and triple-paned configurations), and an expanded metal mesh. This evaluation was performed mainly through computer simulation for a multitude of scenarios, including multiple climates (Chicago, Illinois and Houston, Texas), window-to-wall ratios (0.15-0.60), building codes (ASHRAE 90.1-2004 and 2010) and lighting control configurations (with and without daylighting controls). Angular selective shading systems are optically complex and cannot be modeled accurately using conventional simulation tools, prompting the development of unique versions of the EnergyPlus, Radiance and Window simulation tools. Results show significant potential reductions in perimeter zone energy use, with the best commercially-available system reaching 28% and 47% savings, relative to ASHRAE 90.1- 2004 and respectively without and with daylighting controls, on south facades in Chicago with WWR=0.45, while constraining peak window heat gains to under 43 W/m2-floor, and enabling significant savings from daylighting controls. Results suggest that it is possible that existing systems can be improved to more consistently achieve 30-50% energy savings. Level of angular selectivity, spectral selectivity of low-e coatings and thermal conductance of the angle-selective layer were identified as critical factors for the performance of angular selective systems. Static, angular selective shading systems offer a potentially low-cost option to significantly reduce window heat gains and control glare from visibility of the sun orb, while permitting the admission of useful daylight and access to views to the outdoors. This type of system shows significant potential to contribute towards net-zero energy goals in both new and retrofit construction.

%P 36 %8 01/2014 %9 DOE / CEC PIER Technical Report %2 LBNL-187060 %0 Report %D 2014 %T COMFEN – Early Design Tool for Commercial Facades and Fenestration Systems %A Stephen E. Selkowitz %A Robert J. Hitchcock %A Robin Mitchell %A Maurya McClintock %A Kevin Settlemyre %X

California leads the nation in building energy efficiency standards and is a leader in the United States for legislation to reduce greenhouse gas emissions. Achieving these goals in practice requires that design teams and owners have access to technologies, systems and decision support tools that support their design work. This California Energy Commission funded work on the COMFEN software tool, which gives building practitioners, such as architects and engineers, the ability to assess the energy consequences of building design decisions, is thus a key enabling element that supports the AEC community in achieving ever more stringent performance requirements. COMFEN can provide needed building design guidance to not achieve the shorter term code goals but supports more aggressive achievement of the net-zero energy performance and peak load reduction required for all new buildings by 2030 as well as supporting deep retrofit of existing building stock.

Achieving a net-zero energy building cannot be done solely by improving the efficiency of the engineering systems (HVAC, lighting, equipment). It also requires consideration of the essential nature of the building starting early in the design process, including factors such as architectural form, massing, orientation and enclosure. Making informed decisions about the fundamental character of a building requires continuous assessment of the effects of the complex interaction of these factors on the resulting performance of the building as the design evolves. The complexity of these interactions necessitates the use of modeling and simulation tools to dynamically analyze the effects of the relationships. Decisions about the building fundamentals are often made in the earliest stages of design, before a complete 'building' exists to model so that a focus on representative spaces in the building allows earlier guidance for the decision making.

COMFEN, an early-design energy modeling tool developed by LBNL, is designed specifically to make informed decisions about building fundamentals by considering the design of the building envelope, orientation and massing on building performance. It supports exploratory work early in the process by architects but is also useful for engineers and consultants later in the design process. It also supports innovation broadly as it allows teams to model new technologies and systems that are becoming available but have not yet reached mainstream status.

COMFEN focuses on the concept of a "space" or "room" and uses the EnergyPlus and Radiance™ engines and a simple, graphic user interface to allow the user to explore the effects of changing key early-design input variables for the façade, internal loads, lighting controls and HVAC system on energy consumption, peak energy demand, and thermal and visual comfort. COMFEN also provides the ability to import glazing systems that have been developed in Window7, utilizing the International Glazing DataBase (IGDB) for glass choices. Comparative results are rapidly presented in a variety of graphic and tabular formats to help users move toward optimal façade and fenestration design choices.

While the underlying simulation engines were developed over time as part of DOE's national windows and daylighting program, the specific design features of COMFEN were evolved over a several year period by consulting with a series of largely California-based architectural and engineering firms who provided important guidance and feedback on desirable features and then on functionality once the features were implemented.

COMFEN is available at no charge on the LBNL website.

%8 03/2014 %0 Report %D 2014 %T High Performance Building Façade Solutions-Phase II %A Eleanor S. Lee %A Brian E. Coffey %A Luis L. Fernandes %A Sabine Hoffmann %A Andrew McNeil %A Anothai Thanachareonkit %A Gregory J. Ward %K automated shading %K between-pane shading %K bidirectional scattering distribution functions %K building energy simulation tools %K Complex fenestration systems %K daylighting %K daylighting simulation tools %K electrochromics %K exterior shading %K goniophotometer %K light shelves %K microprismatic films %K model predictive controls %K motorized shading %K shading %K solar-optical properties %K switchable windows %K thermochromics %K virtual prototyping %K window heat transfer %X

The High Performance Building Façade Solutions–Phase II project was initiated through the California Energy Commission’s Public Interest Energy Research (PIER) program in July 2010 to support industry’s development and deployment of both incremental and breakthrough façade technologies in partnership with the U.S. Department of Energy (DOE). The objective of this three-year project was to develop, or support the development and deployment of, promising near-term and emerging zero net energy building façade technologies for solar control and daylighting, addressing two of the largest end uses in California commercial buildings: cooling and lighting. In partnership with industry (such as manufacturers), three classes of technologies were investigated: daylighting systems, angular-selective shading systems, and dynamic façade systems. Commercially available and emerging prototype technologies were developed and evaluated using laboratory tests. Simulations, full-scale outdoor tests in the Advanced Window Testbed, and demonstration projects quantified energy and peak electric demand reductions and occupant satisfaction, acceptance, and comfort associated with the resultant indoor environment. Several new technologies were developed using virtual prototyping tools. Integrated control systems were developed using model predictive controls. Simulation tools were developed to model operable complex fenestration systems such as shades and microprismatic films. A schematic design tool called COMFEN was developed to facilitate evaluation of these advanced technologies in the early design phase. All three classes of technologies resulted in significant reductions in perimeter zone energy use and peak electric demand, providing viable options that can support California’s long-term goal of achieving zero net energy use in the next decade.

%8 03/2014 %2 LBNL-1004337 %0 Journal Article %J Solar Energy Materials and Solar Cells %D 2013 %T An empirical study of a full-scale polymer thermochromic window and its implications on material science development objectives %A Eleanor S. Lee %A Xiufeng Pang %A Sabine Hoffmann %A Howdy Goudey %A Anothai Thanachareonkit %K buildings energy efficiency %K Solar control %K Thermochromic %K windows %X

Large-area polymer thermochromic (TC) laminated windows were evaluated in a full-scale testbed office. The TC interlayer film exhibited thermochromism through a ligand exchange process, producing a change in solar absorption primarily in the visible range while maintaining transparent, undistorted views through the material. The film had a broad switching temperature range and when combined to make an insulating window unit had center-of-glass properties of Tsol=0.12-0.03, Tvis=0.28-0.03 for a glass temperature range of 24-75°C. Field test measurements enabled characterization of switching as a function of incident solar irradiance and outdoor air temperature, illustrating how radiation influences glass temperature and thus effectively lowers the critical switching temperature of TC devices. This was further supported by EnergyPlus building energy simulations. Both empirical and simulation data were used to illustrate how the ideal critical switching temperature or temperature range for TC devices should be based on zone heat balance, not ambient air temperature. Annual energy use data are given to illustrate the energy savings potential of this type of thermochromic. Based on observations in the field,a broad switching temperature range was found to be useful in ensuring a uniform appearance when incident irradiance is non-uniform across the facade. As indicated in prior research, a high visible transmittance in both the switched and unswitched state is also desirable to enable reduction of lighting energy use and enhance indoor environmental quality.

%B Solar Energy Materials and Solar Cells %V 116 %P 14-26 %8 09/2013 %2 LBNL-6376E %& 14 %R 10.1016/j.solmat.2013.03.043 %0 Report %D 2013 %T A Pilot Demonstration of Electrochromic and Thermochromic Windows in the Denver Federal Center, Building 41, Denver, Colorado %A Eleanor S. Lee %A Luis L. Fernandes %A Howdy Goudey %A Jacob C. Jonsson %A Dragan C. Curcija %A Xiufeng Pang %A Dennis L. DiBartolomeo %A Sabine Hoffmann %K building controls %K daylighting %K Demand Side Management %K electrochromic %K energy-efficiency %K Smart windows %K switchable windows %K Thermochromic %K Window %X

Chromogenic glazing materials are emerging technologies that tint reversibly from a clear to dark tinted state either passively in response to environmental conditions or actively in response to a command from a switch or building automation system. Switchable coatings on glass manage solar radiation and visible light while enabling unobstructed views to the outdoors. Building energy simulations estimate that actively controlled, near-term chromogenic glazings can reduce perimeter zone heating, ventilation, and air- conditioning (HVAC) and lighting energy use by 10-20% and reduce peak electricity demand by 20-30%, achieving energy use levels that are lower than an opaque, insulated wall.

This project demonstrates the use of two types of chromogenic windows: thermochromic and electrochromic windows. By 2013, these windows will begin production in the U.S. by multiple vendors at high-volume manufacturing plants, enabling lower cost and larger area window products to be specified. Both technologies are in the late R&D stage of development, where cost reductions and performance improvements are underway. Electrochromic windows have been installed in numerous buildings over the past four years, but monitored energy-efficiency performance has been independently evaluated in very limited applications. Thermochromic windows have been installed in one other building with an independent evaluation, but results have not yet been made public.

%8 07/2013 %U http://gsa.gov/portal/content/187967 %2 LBNL-1005095 %0 Report %D 2013 %T A Post-Occupancy Monitored Evaluation of the Dimmable Lighting, Automated Shading, and Underfloor Air Distribution System in The New York Times Building %A Eleanor S. Lee %A Luis L. Fernandes %A Brian E. Coffey %A Andrew McNeil %A Robert D. Clear %A Thomas L. Webster %A Fred S. Bauman %A Darryl J. Dickerhoff %A David Heinzerling %A Tyler Hoyt %X

With aggressive goals to reduce national energy use and carbon emissions, the US Department of Energy will be looking to exemplary buildings that have already invested in new approaches to achieving the energy performance goals now needed at a national level. The New York Times Building, in New York, New York, incorporates a number of innovative technologies, systems and processes and could become a model for widespread replication in new and existing buildings. Post-occupancy data are invaluable in establishing confidence in innovation. A year-long monitored study was conducted to verify energy performance, assess occupant comfort and satisfaction with the indoor environment, and evaluate impacts on maintenance and operations. Lessons learned were derived from the analysis; these lessons could help identify and shape policy, financial, or supporting strategies to accelerate diffusion in the commercial building market.

%I Lawrence Berkeley National Laboratory %C Berkeley, CA %8 01/2013 %2 LBNL-6023E %0 Journal Article %J Energy and Buildings %D 2013 %T U.S. energy savings potential from dynamic daylighting control glazings %A Arman Shehabi %A Nicholas DeForest %A Andrew McNeil %A Eric R. Masanet %A Jeffery B. Greenblatt %A Eleanor S. Lee %A Georgeta Masson %A Brett A. Helms %A Delia J. Milliron %K Clerestories %K daylighting %K Dynamic prismatic optical elements (dPOE) %K energy efficiency %K Glare %K indoor environmental quality %K radiance %K windows %X

Daylighting controls have the potential to reduce the substantial amount of electricity consumed for lighting in commercial buildings. Material science research is now pursuing the development of a dynamic prismatic optical element (dPOE) window coating that can continuously readjust incoming light to maximize the performance and energy savings available from daylighting controls. This study estimates the technical potential for energy savings available from vertical daylighting strategies and explores additional savings that may be available if current dPOE research culminates in a successful market-ready product. Radiance daylight simulations are conducted with a multi-shape prismatic window coating. Simulated lighting energy savings are then applied to perimeter floorspace estimates generated from U.S. commercial building stock data. Results indicate that fully functional dPOE coatings, when paired with conventional vertical daylight strategies, have the potential to reduce energy use associated with U.S. commercial electric lighting demand by as much as 930 TBtu. This reduction in electric lighting demand represents an approximately 85% increase in the energy savings estimated from implementing conventional vertical daylight strategies alone. Results presented in this study provide insight into energy and cost performance targets for dPOE coatings, which can help accelerate the development process and establish a successful new daylighting technology.

%B Energy and Buildings %V 66 %P 415-423 %8 11/2013 %& 415 %R 10.1016/j.enbuild.2013.07.013 %0 Conference Paper %B SimBuild 2012, 5th National Conference of IBPSA-USA, August 1-3, 2012 %D 2012 %T Application of a stochastic window use model in EnergyPlus %A Spencer M. Dutton %A Hui Zhang %A Yongchao Zhai %A Edward A. Arens %A Youness Bennani Smires %A Samuel L. Brunswick %A Kyle S. Konis %A Philip Haves %X

Natural ventilation, used appropriately, has the potential to provide both significant HVAC energy savings, and improvements in occupant satisfaction.

Central to the development of natural ventilation models is the need to accurately represent the behavior of building occupants. The work covered in this paper describes a method of implementing a stochastic window model in EnergyPlus. Simulated window use data from three stochastic window opening models was then compared to measured window opening behavior, collected in a naturally-ventilated office in California. Recommendations regarding the selection of stochastic window use models, and their implementation in EnergyPlus, are presented.

%B SimBuild 2012, 5th National Conference of IBPSA-USA, August 1-3, 2012 %C Madison, WI %8 08/2012 %U https://escholarship.org/uc/item/2gm7r783 %0 Generic %D 2012 %T Electro-Responsive Polymer Glazings For Smart Windows With Dynamic Daylighting Control %A Georgeta Masson %A Rueben Mendlesberg %A Irene Fernandez-Cuesta %A Stefano Cabrini %A Delia J. Milliron %A Brett A. Helms %A Eleanor S. Lee %A Andrew McNeil %A Stephen E. Selkowitz %X

In the context of alarming phenomenon of global warming with harmful consequences such as increased green house gases beyond predictions, the development of advanced energy efficient technologies became of a primary importance. Since the building sector accounts for 39% of total US primary energy consumption, fenestration can significantly contribute to lowering the energy use for heating, cooling, and lighting. An estimated 9% reduction in total US building energy use, or 3.47 Q, could be attained by dynamic solar/thermal control and daylighting if these advanced optical technologies were adopted throughout the residential and commercial building sectors. In spite of the great research and engineering efforts in the fast growing area of smart windows, development of glazing devices able to provide efficient, durable, and inexpensive products for dynamic daylight control is in infancy. Like the electrochromic glazings now emerging on the market, microscale, switchable daylight-redirecting glazings have the potential for widespread application if a low-cost, durable coating can be engineered and manufactured with the proper set of attributes.

Here we report on the development of a new technology using smart materials for switchable daylight-redirecting glazings. The proposed system consists in a prismatic optical element (POE) fabricated by micro-imprinting of an elastic redox-active polymer network capable to change its geometry and thereby its optical properties in response to an external stimulus. It is expected that the prismatic optical element reversibly collapses in response to an applied potential, thereby modulating the fraction of light which is redirected. The fabrication of the dynamic prismatic optical element from simulation-driven design to materials synthesis and device integration will be described. Investigation of specto-electrochemical characteristics of the redox-active grating and challenges encountered with respect to electromechanical induced structural changes will be also presented.

%8 02/2012 %G eng %0 Journal Article %J Solar Energy Materials and Solar Cells %D 2012 %T Fenestration of Today and Tomorrow: A State-of-the-Art Review and Future Research Opportunities %A Bjørn Petter Jelle %A Andrew Hynd %A Arlid Gustavsen %A Dariush K. Arasteh %A Howdy Goudey %A Robert Hart %K Fenestration %K Low-e %K Multilayer glazing %K Smart window %K Solar cell glazing %K Vacuum glazing %X

Fenestration of today is continuously being developed into the fenestration of tomorrow, hence offering a steadily increase of daylight and solar energy utilization and control, and at the same time providing a necessary climate screen with a satisfactory thermal comfort. Within this work a state of the art market review of the best performing fenestration products has been carried out, along with an overview of possible future research opportunities for the fenestration industry. The focus of the market review was low thermal transmittance (U-value). The lowest centre of glass Ug-values found was 0.28 W/(m2K) and 0.30 W/(m2K), which was from a suspended coating glazing product and an aerogel glazing product, respectively. However, the majority of high performance products found were triple glazed. The lowest frame U-value was 0.61 W/(m2K). Vacuum glazing, smart windows, solar cell glazing, window frames, self cleaning glazing, low-emissivity coatings and spacers were also reviewed, thus also representing possibilities for controlling and harvesting the solar radiation energy. Currently, vacuum glazing, new spacer materials and solutions, electrochromic windows and aerogel glazing seem to have the largest potential for improving the thermal performance and daylight and solar properties in fenestration products. Aerogel glazing has the lowest potential U-values, ~ 0.1 W/(m2K), but requires further work to improve the visible transmittance. Electrochromic vaccum glazing and evacuated aerogel glazing are two vacuum related solutions which have a large potential. There may also be opportunities for completely new material innovations which could revolutionize the fenestration industry.

%B Solar Energy Materials and Solar Cells %V 96 %P 1-28 %8 01/2012 %G eng %1

Windows and Daylighting Group

%2 LBNL-5304E %& 1 %R 10.1016/j.solmat.2011.08.010 %0 Journal Article %J Journal of Materials Research %D 2012 %T Improved structural and electrical properties of thin ZnO:Al films by dc filtered cathodic arc deposition %A Yuankun Zhu %A Rueben J. Mendelsberg %A Sunnie H.N. Lim %A Jiaqi Zhu %A Jiecai Han %A André Anders %K physical vapor deposition %K Plasma deposition %K Transparent conductor %X

Transparent conducting oxide films are usually several 100-nm thick to achieve the required low sheet resistance. In this study, we show that the filtered cathodic arc technique produces high-quality low-cost ZnO:Al material for comparably smaller thicknesses than achieved by magnetron sputtering, making arc deposition a promising choice for applications requiring films less than 100-nm thick. A mean surface roughness less than 1 nm is observed for ZnO:Al films less than 100-nm thick, and 35-nm-thick ZnO:Al films exhibit Hall mobility of 28 cm2/Vs and a low resistivity of 6.5 × 10−4 Ωcm. Resistivity as low as 5.2 × 10−4 Ωcm and mobility as high as 43.5 cm2/Vs are obtained for 135-nm films.

%B Journal of Materials Research %V 27 %P 857 - 862 %8 3/2012 %N 05 %! J. Mater. Res. %R 10.1557/jmr.2011.342 %0 Journal Article %J Journal of Physics D: Applied Physics %D 2012 %T The ‘recycling trap’: a generalized explanation of discharge runaway in high-power impulse magnetron sputtering %A André Anders %A Jiří Čapek %A Matêj Hála %A Ludvik Martinu %X

Contrary to paradigm, magnetron discharge runaway cannot always be related to self-sputtering. We report here that the high density discharge can be observed with all conducting targets, including low sputter yield materials such as carbon. Runaway to a high density discharge is therefore generally based on self-sputtering in conjunction with the recycling of gas atoms in the magnetic field-affected pre-sheath. A generalized runaway condition can be formulated, offering a pathway to a time-dependent model for high-power impulse magnetron sputtering that includes rarefaction and an explanation for the termination of runaway.

%B Journal of Physics D: Applied Physics %V 45 %P 012003 %8 01/2012 %N 1 %! J. Phys. D: Appl. Phys. %R 10.1088/0022-3727/45/1/012003 %0 Report %D 2010 %T Post Occupancy Study of The New York Times Building: Survey Findings Assessing Occupant Comfort and Satisfaction %A Adam Hinge %X

The New York Times (NY Times) building located at 620 Eighth Avenue in Manhattan was designed to include state of the art, environmentally-sustainable features intended to enhance occupant satisfaction and save energy. Some of the features in the NY Times space, including daylight dimming controls, automated window shades, and an advanced under-floor air distribution (UFAD) system, were first of their kind ventures on this scale in the US. The New York State Energy Research & Development Authority (NYSERDA) actively supported the design and construction of this new facility with significant incentives toward the innovative features of the facility.

In order to understand occupant satisfaction and comfort levels associated with these new technologies, NYSERDA is providing support to the NY Times Facility Management staff with a simplified post occupancy review, assisting with development and analysis of an occupant satisfaction survey. The survey (survey instrument attached as Appendix 2) was intended to determine the level of occupant satisfaction with certain aspects of the indoor environmental quality of the NY Times Building, with a special focus on lighting and comfort quality provided by the innovative lighting/shading control and UFAD systems. In distributing the survey, it was stated that results from the survey would be shared with occupants, and will also inform Facilities Management in their operation of the building.

%C Tarrytown, New York %8 11/2010 %9 Final report by Sustainable Energy Partnerships %( Final report by Sustainable Energy Partnerships %0 Journal Article %J Lighting Research + Technology %D 2009 %T Daylight metrics and energy savings %A John Mardaljevic %A Lisa Heschong %A Eleanor S. Lee %X

The drive towards sustainable, low-energy buildings has increased the need for simple, yet accurate methods to evaluate whether a "daylit" building meets minimum standards for energy and human comfort performance. Current metrics do not account for the temporal and spatial aspects of daylight, nor of occupants comfort or interventions. This paper reviews the historical basis of current compliance methods for achieving daylit buildings, proposes a technical basis for development of better metrics, and provides two case study examples to stimulate dialogue on how metrics can be applied in a practical, real-world context.

%B Lighting Research + Technology %V 41 %P 261-283 %8 09/2009 %G eng %N 3 %1

Windows and Daylighting Group

%2 LBNL-4585E %& 261 %R 10.1177/1477153509339703 %0 Report %D 2009 %T High Performance Building Facade Solutions: PIER Final Project Report %A Eleanor S. Lee %A Stephen E. Selkowitz %A Dennis L. DiBartolomeo %A Joseph H. Klems %A Robert D. Clear %A Kyle S. Konis %A Robert J. Hitchcock %A Mehry Yazdanian %A Robin Mitchell %A Maria Konstantoglou %X

Building façades directly influence heating and cooling loads and indirectly influence lighting loads when daylighting is considered, and are therefore a major determinant of annual energy use and peak electric demand. façades also significantly influence occupant comfort and satisfaction, making the design optimization challenge more complex than many other building systems.

This work focused on addressing significant near-term opportunities to reduce energy use in California commercial building stock by a) targeting voluntary, design-based opportunities derived from the use of better design guidelines and tools, and b) developing and de ploying more efficient glazings, shading systems, daylighting systems, façade systems and integrated controls.

This two-year project, supported by the California Energy Commission PIER program and the US Department of Energy, initiated a collaborative effort between The Lawrence Berkeley National Laboratory (LBNL) and major stakeholders in the façades industry to develop, evaluate, and accelerate market deployment of emerging, high-performance, integrated façade solutions. The LBNL Windows Testbed Facility acted as the primary cata lyst and mediator on both sides of the building industry supply-user business transaction by a) aiding component suppliers to create and optimize cost effective, integrated systems that work, and b) demonstrating and verifying to the owner, designer, and specifier community that these integrated systems reliably deliver required energy performance. An industry consortium was initiated amongst approximately seventy disparate stakeholders, who unlike the HVAC or lighting industry, has no single representative, multi-disciplinary body or organized means of communicating and collaborating. The consortium provided guidance on the project and more importantly, began to mutually work out and agree on the goals, criteria, and pathways needed to attain the ambitious net zero energy goals defined by California and the US.

A collaborative test, monitoring, and reporting protocol was also formulated via the Windows Testbed Facility in collaboration with industry partners, transitioning industry to focus on the import ance of expecting measured performance to consistently achieve design performance expectations. The facility enables accurate quantification of energy use, peak demand, and occupant comfort impacts of synergistic façade-lighting-HVAC systems on an apples-to-apples comparative basis and its data can be used to verify results from simulations.

Emerging interior and exterior shading technologies were investigated as potential near-term, low-cost solutions with potential broad applicability in both new and retrofit construction. Commercially-available and prototype technologies were developed, tested, and evaluated. Full-scale, monitored field tests were conducted over solstice-to-solstice periods to thoroughly evaluate the technologies, uncover potential risks associated with an unknown, and quantify performance benefits. Exterior shading systems were found to yield net zero energy levels of performance in a sunny climate and significant reductions in summer peak demand. Automated interior shading systems were found to yield significant daylighting and comfort-related benefits.

In support of an integrated design process, a PC-based commercial fenestration (COMFEN) software package, based on EnergyPlus, was developed that enables architects and engineers to x quickly assess and compare the performance of innovative façade technologies in the early sketch or schematic design phase. This tool is publicly available for free and will continue to improve in terms of features and accuracy. Other work was conducted to develop simulation tools to model the performance of any arbitrary complex fenestration system such as common Venetian blinds, fabric roller shades as well as more exotic innovative façade systems such as optical louver systems.

The principle mode of technology transfer was to address the key market barriers associated with lack of information and facile simulation tools for early decisionmaking. The third party data generated by the field tests and simulation data provided by the COMFEN tool enables utilities to now move forward toward incentivizing these technologies in the marketplace.

%8 12/2009 %G eng %1

Windows and Daylighting Group

%2 LBNL-4583E %0 Conference Paper %B SimBuild 2008, July 30-August 1 %D 2008 %T A Modular Building Controls Virtual Test Bed for the Integration of Heterogeneous Systems %A Michael Wetter %A Philip Haves %X

This paper describes the Building Controls Virtual Test Bed (BCVTB) that is currently under development at Lawrence Berkeley National Laboratory. An earlier prototype linked EnergyPlus with controls hardware through embedded SPARK models and demonstrated its value in more cost-effective envelope design and improved controls sequences for the San Francisco Federal Building. The BCVTB presented here is a more modular design based on a middleware that we built using Ptolemy II, a modular software environment for design and analysis of heterogeneous systems. Ptolemy II provides a graphical model building environment, synchronizes the exchanged data and visualizes the system evolution during run-time. Our additions to Ptolemy II allow users to couple to Ptolemy II a prototype version of EnergyPlus, MATLAB/Simulink or other simulation programs for data exchange during run-time. In future work we will also implement a BACnet interface that allows coupling BACnet compliant building automation systems to Ptolemy II. We will present the architecture of the BCVTB and explain how users can add their own simulation programs to the BCVTB. We will then present an example application in which the building envelope and the HVAC system was simulated in EnergyPlus, the supervisory control logic was simulated in MATLAB/Simulink and Ptolemy II was used to exchange data during run-time and to provide real-time visualization as the simulation progresses.

%B SimBuild 2008, July 30-August 1 %C Berkeley, CA %8 08/2008 %G eng %2 LBNL-650E %0 Journal Article %J Journal of Physics D %D 2008 %T Spatial distribution of average charge state and deposition rate in high power impulse magnetron sputtering of copper %A David Horwat %A André Anders %X

The spatial distribution of copper ions and atoms in high power impulse magnetron sputtering (HIPIMS) discharges was determined by (i) measuring the ion current to electrostatic probes and (ii) measuring the film thickness by profilometry. A set of electrostatic and collection probes were placed at different angular positions and distances from the target surface. The angular distribution of the deposition rate and the average charge state of the copper species (including ions and neutrals) were deduced. The discharge showed a distinct transition to a high current mode dominated by copper self-sputtering when the applied voltage exceeded the threshold of 535 V. For a lower voltage, the deposition rate was very low and the average charge state was found to be less than 0.4. For higher voltage (and average power), the absolute deposition rates were much higher, but they were smaller than the corresponding direct current (DC) rates if normalized to the same average power. At the high voltage level, the spatial distribution of the average charge state showed some similarities with the distribution of the magnetic field, suggesting that the generation and motion of copper ions is affected by magnetized electrons. At higher voltage, the average charge state increases with the distance from the target and locally may exceed unity, indicating the presence of significant amounts of doubly charged copper ions.

%B Journal of Physics D %V 41 %P 135210-1-6 %G eng %L LBNL-679E %1

Windows and Daylighting Group

%2 LBNL-679E %0 Report %D 2008 %T WINDOW 6.2/THERM 6.2 Research Version User Manual %A Robin Mitchell %A Christian Kohler %A Joseph H. Klems %A Michael D. Rubin %A Dariush K. Arasteh %A Charlie Huizenga %A Tiefeng Yu %A Dragan C. Curcija %X

WINDOW 6 and THERM 6 Research Versions are software programs developed at Lawrence Berkeley National Laboratory (LBNL) for use by manufacturers, engineers, educators, students, architects, and others to determine the thermal and solar optical properties of glazing and window systems.

WINDOW 6 and THERM 6 are significant updates to LBNL's WINDOW 5 and THERM 5 computer program because of the added capability to model complex glazing systems, such as windows with shading systems, in particular venetian blinds. Besides a specific model for venetian blinds and diffusing layers, WINDOW 6 also includes the generic ability to model any complex layer if the Transmittance and Reflectance are known as a function of incoming and outgoing angles.

The algorithms used in these versions of the programs to determine the properties of windows with shading layers are relatively new and should be considered as informative but not definitive.

As such, for windows with shading layers, the results are intended for research purposes only. Pending further validation efforts, results for windows with sh ading layers should not be used for NFRC certified calculations of design decisions in real buildings.

All calculations for products without shading layers are identical to those from WINDOW 5.2.

WINDOW 6 Research Version includes all of the WINDOW 5 capabilities with the addition of shading algorithms from ISO15099 which are incorporated into the program, as well as an extension of those algorithms with the matrix calculation method.

THERM 6 Research Version includes all of the THERM 5 capabilities with the addition of being able to import and model WINDOW 6 glazing systems with shading devices. Those THERM 6 files with shading devices can them be imported into the WINDOW 6 Frame Library and whole windows with shading devices can then be modeled in WINDOW 6.

%I Lawrence Berkeley National Laboratory %C Berkeley %P 1-126 %8 01/2008 %G eng %1

Windows and Daylighting Group

%2 LBNL-813E %0 Report %D 2007 %T Daylighting the New York Times Headquarters Building: Final Report: Commissioning Daylighting Systems and Estimation of Demand Response %A Eleanor S. Lee %A Glenn D. Hughes %A Robert D. Clear %A Luis L. Fernandes %A Sila Kiliccote %A Mary Ann Piette %A Francis M. Rubinstein %A Stephen E. Selkowitz %K automated daylighting controls %K automated window shades %K daylighting %K demand response %K energy-efficiency %K visual comfort %X

The technical energy-savings potential for smart integrated window-daylighting systems is excellent and can yield significant reductions in US commercial building energy use if adopted by a significant percentage of the market. However, conventional automated shades and daylighting controls have been commercially available for over two decades with less than 1-2% market penetration in the US. As with many innovations, the problem with accelerating market adoption is one of demonstrating real performance and decreasing risk and cost. The New York Times considered use of such daylighting systems for their new 139,426 m2 (1.5 Mft2) headquarters building in downtown Manhattan.

In the initial phase of work, The New York Times employed a unique approach to create a competitive marketplace for daylighting systems and to address their concerns about risk by building a full-scale daylighting mockup and evaluating commercially-available products. This field test formed the strategic cornerstone for accelerating an industry response to the building owners' challenge to a sleepy market. A procurement specification was produced and bids were received that met The Times cost-effective criteria. The Times decided to proceed with using these innovative systems in their new building.

This next phase of work consisted of two distinct tasks: 1) to develop and use commissioning tools and procedures to insure that the automated shade and daylighting control systems operate as intended prior to occupancy; and 2) to estimate the peak demand savings resulting from different levels of demand response (DR) control strategies (from moderate to severe load curtailment) and then determine the financial implications given various DR programs offered by the local utility and New York Independent System Operator in the area.

Commissioning daylighting control systems is mandatory to insure that design intent is met, that the systems are tuned to optimal performance, and to eliminate problems and errors before occupants move in. Commissioning tools were developed and procedures were defined and then used to verify that the daylighting systems operated according to the technical specifications. For both lighting control and shading systems, the Times and the manufacturers were able to resolve most of the bugs and fine-tune the systems prior to occupancy.

The demand response (DR) strategies at the New York Times building involve unique state-of-the-art systems with dimmable ballasts, movable shades on the glass facade, and underfloor air HVAC. The process to develop the demand response strategies, the results of the EnergyPlus model, the activities to implement the DR strategies in the controls design at the New York Times Headquarters building and the evaluation of economics of participating in DR programs are presented and discussed. The DR simulation iv efforts for this building design are novel, with an innovative building owner evaluating DR and future DR program participation strategies during the design and construction phase using advanced simulation tools.

%C Berkeley %8 08/2007 %0 Report %D 2007 %T Moving from Niche to Mainstream Markets: Addressing the High Cost of Daylighting Systems %A Glenn D. Hughes %X

Transcript of a lecture given by Glenn Hughes, Managing Director of Construction, The New York Times at LightFair International: Daylighting Institute, New York, New York, May 6, 2007.

%C New York, New York %8 05/2007 %0 Conference Paper %B ISSP2007: The 9th International Symposium on Sputtering & Plasma Processes %D 2007 %T Physics of High Power Impulse Magnetron Sputtering %A André Anders %A Joakim Andersson %A David Horwat %A Arutiun P. Ehiasarian %X

High power impulse magnetron sputtering is characterized by discharge pulses whose target power density exceeds conventional sputtering power densities by two orders of magnitude or more; the goal is to provide a large flux of ionized sputtered material. The processes of pulse evolution are briefly reviewed, including secondary electron emission, self-sputtering, and rarefaction. Using a pulse power supply capable of providing constant voltage for target peak power densities up to 5 kW/cm2, the evolution of the current-voltage characteristics was investigated for copper and titanium. It is shown that the characteristic cannot be reduced to value pairs. Rather, a strong but reproducible development exists. The details depend on the argon pressure and applied voltage. Each target material exhibits a distinct and sharp transition to a high current regime that appears to be dominated by metal plasma. Despite the higher sputter yields for copper, the transition to the high current regime occurs much earlier and stronger for titanium, which may be attributed to a higher secondary electron yield and hence a higher density of electrons confined in the magnetron structure. At high currents, the closed-drift Hall current generates a magnetic field that weakens plasma confinement, thereby enabling large ion currents to reach a biased substrate.

%B ISSP2007: The 9th International Symposium on Sputtering & Plasma Processes %G eng %L LBNL-62147 %1

Windows and Daylighting Group

%2 LBNL-62147 %0 Conference Paper %B 2006 ACEEE Summer Study on Energy Efficiency in Buildings %D 2006 %T Dynamic Controls for Energy Efficiency and Demand Response: Framework Concepts and a New Construction Case Study in New York %A Sila Kiliccote %A Mary Ann Piette %A David S. Watson %A Glenn D. Hughes %X

Many of today's advanced building control systems are designed to improve granularity of control for energy efficiency. Examples include direct digital controls for building heating, ventilation, and cooling systems (HVAC), and dimmable ballasts for continuous dimming for daylighting applications. This paper discusses recent research on the use of new and existing controls in commercial buildings for integrated energy efficiency and demand response (DR). The paper discusses the use of DR controls strategies in commercial buildings and provides specific details on DR control strategy design concepts for a new building in New York. We present preliminary results from EnergyPlus simulations of the DR strategies at the New York Times Headquarters building currently under construction. The DR strategies at the Times building involve unique state of the art systems with dimmable ballasts, movable shades on the glass facade, and underfloor air HVAC. The simulation efforts at this building are novel, with an innovative building owner considering DR and future DR program participation strategies during the design phase. This paper also discusses commissioning plans for the DR strategies. The trends in integration of various systems through the EMCS, master versus supervisory controls and dynamic operational modes concepts are presented and future research directions are outlined.

%B 2006 ACEEE Summer Study on Energy Efficiency in Buildings %C Pacific Grove, CA %8 06/2006 %G eng %2 LBNL-60615 %4

August 13-18, 2006

%#

demand response

%$

Commercial Building Systems Group

%]

y

%0 Conference Paper %B SimBuild 2006: Building Sustainability and Performance Through Simulation %D 2006 %T Evaluating Fenestration Products for Zero-Energy Buildings: Issues for Discussion %A Dariush K. Arasteh %A Dragan C. Curcija %A Yu Joe Huang %A Charlie Huizenga %A Christian Kohler %X

Computer modeling to determine fenestration product energy properties (U-factor, SHGC, VT) has emerged as the most cost-effective and accurate means to quantify them. Fenestration product simulation tools have been effective in increasing the use of low-e coatings and gas fills in insulating glass and in the widespread use of insulating frame designs and materials. However, for more efficient fenestration products (low heat loss products, dynamic products, products with non-specular optical characteristics, light redirecting products) to achieve widespread use, fenestration modeling software needs to be improved.

This paper addresses the following questions:

1) Are the current properties (U, SHGC, VT) calculated sufficient to compare and distinguish between windows suitable for Zero Energy Buildings and conventional window products? If not, what data on the thermal and optical performance, on comfort, and on peak demand of windows is needed.

2) Are the algorithms in the tools sufficient to model the thermal and optical processes? Are specific heat transfer and optical effects not accounted for? Is the existing level of accuracy enough to distinguish between products designed for Zero Energy Buildings? Is the current input data adequate?

%B SimBuild 2006: Building Sustainability and Performance Through Simulation %C Cambridge, MA %8 08/2006 %G eng %L LBNL-61249 %1

Windows and Daylighting Group

%2 LBNL-61249 %0 Conference Paper %B 2007 ASHRAE Winter Meeting %D 2006 %T Performance Criteria for Residential Zero Energy Windows %A Dariush K. Arasteh %A Howdy Goudey %A Yu Joe Huang %A Christian Kohler %A Robin Mitchell %X

This paper shows that the energy requirements for today's typical efficient window products (i.e. ENERGY STAR products) are significant when compared to the needs of Zero Energy Homes (ZEHs). Through the use of whole house energy modeling, typical efficient products are evaluated in five US climates and compared against the requirements for ZEHs. Products which meet these needs are defined as a function of climate. In heating dominated climates, windows with U-factors of 0.10 Btu/hr-ft2-F (0.57 W/m2-K) will become energy neutral. In mixed heating/cooling climates a low U-factor is not as significant as the ability to modulate from high SHGCs (heating season) to low SHGCs (cooling season).

%B 2007 ASHRAE Winter Meeting %C Dallas, TX %8 01/2007 %G eng %L LBNL-59190 %1

Windows and Daylighting Group

%2 LBNL-59190 %0 Report %D 2005 %T Daylighting the New York Times Headquarters Building: Final Report %A Eleanor S. Lee %A Stephen E. Selkowitz %A Glenn D. Hughes %A Robert D. Clear %A Gregory J. Ward %A John Mardaljevic %A Judy Lai %A Mehlika Inanici %A Vorapat Inkarojrit %K automated daylighting controls %K automated window shades %K daylighting %K energy-efficiency %K visual comfort %X

The technical energy-savings potential for smart integrated window-daylighting systems is excellent and can yield significant reductions in US commercial building energy use if adopted by a significant percentage of the market. However, conventional automated shades and daylighting controls have been commercially available for over two decades with less than 1-2% market penetration in the US. As with all innovations, the problem with accelerating market adoption is one of decreasing risk. As the building owner researches technology options, the usual questions surface that concern the purchase of any new product: how will it work for my application, are the vendor claims valid, what risks are incurred, and will the performance benefits be sustained over the life of the installation? In their effort to create an environment that "enhances the way we work" in their new 139 km2 (1.5 Mft2) headquarters building in downtown Manhattan, The New York Times employed a unique approach to create a competitive marketplace for daylighting systems. A monitored field test formed the strategic cornerstone for accelerating an industry response to the building owners' challenge to a sleepy market (i.e., US automated shading and daylighting control products have had few major technical advances over the past 10 years). Energy, control system, and environmental quality performance of commercially-available automated roller shade and daylighting control systems were evaluated. Procurement specifications were produced. Bids were received that met The Times cost-effective criteria. The Times will proceed with the use of these systems in their final building. Competitively-priced new products have been developed as a result of this research and are now available on the market.

%8 06/2005 %2 LBNL-57602 %0 Conference Paper %B Building Simulation 2005 %D 2005 %T DElight2 Daylighting Analysis in Energy Plus: Integration and Preliminary User Results %A William L. Carroll %A Robert J. Hitchcock %X

DElight is a simulation engine for daylight and electric lighting system analysis in buildings. DElight calculates interior illuminance levels from daylight, and the subsequent contribution required from electric lighting to meet a desired interior illuminance. DElight has been specifically designed to integrate with building thermal simulation tools. This paper updates the DElight capability set, the status of integration into the simulation tool EnergyPlus, and describes a sample analysis of a simple model from the user perspective.

%B Building Simulation 2005 %C Montreal, Canada %8 08/2005 %G eng %L LBNL-57531 %1

Windows and Daylighting Group

%2 LBNL-57531 %0 Report %D 2005 %T RESFEN5: Program Description %A Robin Mitchell %A Yu Joe Huang %A Dariush K. Arasteh %A Charlie Huizenga %A Steve Glendenning %X

A computer tool such as RESFEN can help consumers and builders pick the most energy-efficient and cost-effective window for a given application, whether it is a new home, an addition, or a window replacement. It calculates heating and cooling energy use and associated costs as well as peak heating and cooling demand for specific window products. Users define a specific scenario by specifying house type (single-story or two-story), geographic location, orientation, electricity and gas cost, and building configuration details (such as wall, floor, and HVAC system type). Users also specify size, shading, and thermal properties of the window they wish to investigate. The thermal properties that RESFEN requires are: U-factor, Solar Heat Gain Coefficient, and air leakage rate. RESFEN calculates the energy and cost implications of the window compared to an insulated wall. The relative energy and cost impacts of two different windows can be compared.

RESFEN 3.0 was a major improvement over previous versions because it performs hourly calculations using a version of the DOE 2.1E (LBL 1980, Winkelmann et al. 1993) energy analysis simulation program. RESFEN 3.1 incorporates additional improvements including input assumptions for the base case buildings taken from the National Fenestration Rating Council (NFRC) Annual Energy Subcommittee's efforts.

%I Lawrence Berkeley National Laboratory %8 05/2005 %G eng %1

Windows and Daylighting Group

%2 LBNL-812E %0 Conference Paper %B SimBuild 2004 %D 2004 %T Development of Trade-Off Equations for EnergyStar Windows %A Yu Joe Huang %A Robin Mitchell %A Stephen E. Selkowitz %A Dariush K. Arasteh %A Robert D. Clear %X

The authors explore the feasibility of adding a performance option to DOE's EnergyStar© Windows program whereby windows of differing U-factors and SHGCs can qualify so long as they have equivalent annual energy performance. An iterative simulation procedure is used to calculate trade-off equations giving the change in SHGC needed to compensate for a change in U-factor. Of the four EnergyStar© Window climate zones, trade-off equations are possible only in the Northern and Southern zones. In the North/Central and South/Central zones, equations are not possible either because of large intrazone climate variations or the current SHGC requirements are already near optimum.

%B SimBuild 2004 %C Boulder, CO %8 08/2004 %G eng %L LBNL-55517 %1

Windows and Daylighting Group

%2 LBNL-55517 %0 Conference Paper %B 2004 ACEEE Summer Study on Energy Efficiency in Buildings %D 2004 %T Market Transformation Opportunities for Emerging Dynamic Facade and Dimmable Lighting Control Systems %A Eleanor S. Lee %A Stephen E. Selkowitz %A Glenn D. Hughes %A David A. Thurm %X

Automated shading and daylighting control systems have been commercially available for decades. The new challenge is to provide a fully functional and integrated facade and lighting system that operates appropriately for all environmental conditions and meets a range of occupant subjective desires and objective performance requirements. These rigorous performance goals must be achieved with solutions that are cost effective and can operate over long periods with minimal maintenance. It will take time and effort to change the marketplace for these technologies and practices, particularly in building a series of documented success stories, and driving costs and risks to much lower levels at which their use becomes the norm. In recent years, the architectural trend toward highly-transparent all-glass buildings presents a unique challenge and opportunity to advance the market for emerging, smart, dynamic window and dimmable daylighting control technologies.

We believe it is possible to accelerate product market transformation by developing projects where technical advances and the interests of motivated manufacturers and innovative owners converge. In this paper we present a case study example that explains a building owners decision-making process to use dynamic window and dimmable daylighting controls. The case study project undertaken by a major building owner in partnership with a buildings R&D group was designed explicitly to use field test data in conjunction with the market influence of a major landmark building project in New York City to stimulate change in manufacturers product offerings. Preliminary observations on the performance of these systems are made. A cost model that was developed with the building owner is explained.

%B 2004 ACEEE Summer Study on Energy Efficiency in Buildings %C Pacific Grove, CA %8 08/2004 %G eng %1

Windows and Daylighting Group

%2 LBNL-55310 %0 Report %D 2003 %T THERM 5/WINDOW 5 NFRC Simulation Manual %A Robin Mitchell %A Christian Kohler %A Dariush K. Arasteh %A John Carmody %A Charlie Huizenga %A Dragan C. Curcija %X

This document, the THERM 5 / WINDOW 5 NFRC Simulation Manual, discusses how to use the THERM and WINDOW programs to model products for NFRC certified simulations and assumes that the user is already familiar with those programs. In order to learn how to use these programs, it is necessary to become familiar with the material in both the THERM Users Manual and the WINDOW Users Manual. In general, this manual references the Users Manuals rather than repeating the information.

If there is a conflict between either of the User Manual and this THERM 5 / WINDOW 5 NFRC Simulation Manual, the THERM 5 / WINDOW 5 NFRC Simulation Manual takes precedence. In addition, if this manual is in conflict with any NFRC standards, the standards take precedence. For example, if samples in this manual do not follow the current taping and testing NFRC standards, the standards not the samples in this manual, take precedence.

%G eng %L LBNL-48255 %1

Windows and Daylighting Group

%2 LBNL-48255 %0 Conference Paper %B ACEEE 2002 Summer Study on Energy Efficiency in Buildings: Teaming for Efficency %D 2002 %T Active Load Management with Advanced Window Wall Systems: Research and Industry Perspectives %A Eleanor S. Lee %A Stephen E. Selkowitz %A Mark S. Levi %A Steven L. Blanc %A Erin McConahey %A Maurya McClintock %A Pekka Hakkarainen %A Neil L. Sbar %A Michael P. Myser %X

Advanced window wall systems have the potential to provide demand response by reducing peak electric loads by 20-30% in many commercial buildings through the active control of motorized shading systems, switchable window coatings, operable windows, and ventilated double-skin facade systems. These window strategies involve balancing daylighting and solar heat gains, heat rejection through ventilation, and night-time natural ventilation to achieve space-conditioning and lighting energy use reductions without the negative impacts on occupants associated with other demand responsive (DR) strategies.

This paper explores conceptually how advanced window systems fit into the context of active load management programs, which cause customers to directly experience the time-varying costs of their consumption decisions. Technological options are suggested. We present pragmatic criteria that building owners use to determine whether to deploy such strategies. A utility's perspective is given. Industry also provides their perspectives on where the technology is today and what needs to happen to implement such strategies more broadly in the US.

While there is significant potential for these advanced window concepts, widespread deployment is unlikely to occur with business-as-usual practice. Technologically, integrated window-lighting-HVAC products are underdeveloped. Implementation is hindered by fragmented labor practices, non-standard communication protocols, and lack of technical expertise. Design tools and information products that quantify energy performance, occupant impacts, reliability, and other pragmatic concerns are not available. Interest within the building industry in sustainability, energy-efficiency, and increased occupant amenity, comfort, and productivity will be the driving factors for these advanced facades in the near term — at least until the dust settles on the deregulated electricity market.

%B ACEEE 2002 Summer Study on Energy Efficiency in Buildings: Teaming for Efficency %C Pacific Grove, CA %8 08/2002 %G eng %L LBNL-50855 %1

Windows and Daylighting Group

%2 LBNL-50855 %0 Conference Paper %B ASHRAE Transactions %D 2002 %T Future Advanced Windows for Zero-Energy Homes %A Joshua S. Apte %A Dariush K. Arasteh %A Yu Joe Huang %X

Over the past 15 years, low-emissivity and other technological improvements have significantly improved the energy efficiency of windows sold in the United States. However, as interest increases in the concept of zero-energy homes—buildings that do not consume any nonrenewable or net energy from the utility grid—even today's highest-performance window products will not be sufficient. This simulation study compares today's typical residential windows, today's most efficient residential windows, and several options for advanced window technologies, including products with improved fixed or static properties and products with dynamic solar heat gain properties. Nine representative window products are examined in eight representative U.S. climates. Annual energy and peak demand impacts are investigated. We conclude that a new generation of window products is necessary for zero-energy homes if windows are not to be an energy drain on these homes. Windows with dynamic solar heat gain properties are found to offer significant potential in reducing energy use and peak demands in northern and central climates, while windows with very low (static) solar heat gain properties offer the most potential in southern climates.

%B ASHRAE Transactions %C Kansas City, MO %V 109, pt 2 %P 871-888 %8 06/2003 %G eng %L LBNL-51913 %1

Windows and Daylighting Group

%2 LBNL-51913 %0 Conference Paper %B Performance of Exterior Envelopes of Whole Buildings VIII %D 2001 %T Improving Information Technology to Maximize Fenestration Energy Efficiency %A Dariush K. Arasteh %A Robin Mitchell %A Christian Kohler %A Charlie Huizenga %A Dragan C. Curcija %X

Annual heating and cooling energy loads through fenestration products in both residential and commercial buildings are a significant fraction of national energy requirements. In the residential sector, 1.34 and 0.37 quads are required for heating and cooling respectively (DOE Core Data Book, 2000). In commercial buildings, cooling energy use to compensate for fenestration product solar heat gain is estimated at 0.39 quads; heating energy use to compensate for heat loss through fenestration products is estimated at 0.19 quads. Advanced products offer the potential to reduce these energy uses by at least 50% (Frost et. al. 1993). Potential electric lighting savings from fenestration products are estimated at 0.4 quads if daylight can be used effectively so that electric lighting in commercial building perimeter zones can be reduced.

Software has begun to make an impact on the design and deployment of efficient fenestration products by making fenestration product performance ratings widely available. These ratings, which are determined in part using software programs such as WINDOW/THERM/Optics, VISION/FRAME, and WIS, can now easily be used by architects, engineers, professional fenestration product specifiers, and consumers. Information on the properties of fenestration products has also influenced state and national codes (IECC, ASHRAE 90.1) and aided voluntary market transformation programs, such as the Efficient Windows Collaborative and the Energy Star Windows program, which promote efficient fenestration products.

%B Performance of Exterior Envelopes of Whole Buildings VIII %C Clearwater Beach, FL %8 12/2001 %G eng %L LBNL-48147 %1

Windows and Daylighting Group

%2 LBNL-48147 %0 Report %D 2001 %T WINDOW 5.0 User Manual for Analyzing Window Thermal Performance %A Robin Mitchell %A Christian Kohler %A Dariush K. Arasteh %A Charlie Huizenga %A Dragan C. Curcija %G eng %1

Windows and Daylighting Group

%2 LBNL-44789 %0 Report %D 2000 %T THERM 2.1 NFRC Simulation Manual %A Robin Mitchell %A Christian Kohler %A Dariush K. Arasteh %A Elizabeth U. Finlayson %A Charlie Huizenga %A Dragan C. Curcija %A John Carmody %X

This document, the THERM 2.1 NFRC Simulation Manual, discusses how to use THERM to model products for NFRC certified simulations and assumes that the user is already familiar with the THERM program. In order to learn how to use THERM, it is necessary to become familiar with the material in the THERM User's Manual.

In general, this manual references the THERM User's Manual rather than repeating the information.

If there is a conflict between the THERM User's Manual and the THERM 2.1 NFRC Simulation Manual, the THERM 2.1 NFRC Simulation Manual takes precedence.

%P 260 %8 07/2000 %G eng %1

Windows and Daylighting Group

%2 PUB-3147 %0 Conference Paper %B 2000 ASHRAE Winter Meeting %D 1999 %T A Database of Window Annual Energy Use in Typical North American Residences %A Dariush K. Arasteh %A Yu Joe Huang %A Robin Mitchell %A Robert D. Clear %A Christian Kohler %X

This paper documents efforts by the National Fenestration Rating Council to develop a database on annual energy impacts of windows in a typical new, single family, single story residence in various U.S. and Canadian climates. The result is a database of space heating and space cooling energies for 14 typical windows in 52 North American climates. (Future efforts will address the effects of skylights.) This paper describes how this database was created, documents the assumptions used in creating this database, elaborates on assumptions, which need further research, examines the results, and describes the possible uses of the database.

%B 2000 ASHRAE Winter Meeting %C Dallas, Texas %8 02/2000 %G eng %L LBNL-44020 %1

Windows and Daylighting Group

%2 LBNL-44020 %0 Report %D 1999 %T RESFEN 3.1: A PC Program for Calculating the Heating and Cooling Energy Use of Windows in Residential Buildings %A Robin Mitchell %A Yu Joe Huang %A Dariush K. Arasteh %A Robert Sullivan %A Santosh Phillip %X

A computer tool such as RESFEN can help consumers and builders pick the most energy-efficient and cost-effective window for a given application, whether it is a new home, an addition, or a window replacement. It calculates heating and cooling energy use and associated costs as well as peak heating and cooling demand for specific window products. Users define a specific scenario by specifying house type (single-story or two-story), geographic location, orientation, electricity and gas cost, and building configuration details (such as wall, floor, and HVAC system type). Users also specify size, shading, and thermal properties of the window they wish to investigate. The thermal properties that RESFEN requires are: U-factor, Solar Heat Gain Coefficient, and air leakage rate. RESFEN calculates the energy and cost implications of the window compared to an insulated wall. The relative energy and cost impacts of two different windows can be compared.

RESFEN 3.0 was a major improvement over previous versions because it performs hourly calculations using a version of the DOE 2.1E (LBL 1980, Winkelmann et al. 1993) energy analysis simulation program. RESFEN 3.1 incorporates additional improvements including input assumptions for the base case buildings taken from the National Fenestration Rating Council (NFRC) Annual Energy Subcommittee's efforts.

%I Lawrence Berkeley National Laboratory %C Berkeley %8 08/1999 %G eng %1

Windows and Daylighting Group

%2 LBNL-40682 Rev. %0 Conference Paper %B Thermal Performance of the Exterior Envelopes of Buildings VII %D 1999 %T Residential Fenestration Performance Analysis Using RESFEN 3.1 %A Yu Joe Huang %A Robin Mitchell %A Dariush K. Arasteh %A Stephen E. Selkowitz %X

This paper describes the development efforts of RESFEN 3.1, a PC-based computer program for calculating the heating and cooling energy performance and cost of residential fenestration systems. The development of RESFEN has been coordinated with ongoing efforts by the National Fenestration Rating Council (NFRC) to develop an energy rating system for windows and skylights to maintain maximum consistency between RESFEN and NFRCs planned energy rating system. Unlike previous versions of RESFEN, that used regression equations to replicate a large data base of computer simulations, Version 3.1 produces results based on actual hour-by-hour simulations. This approach has been facilitated by the exponential increase in the speed of personal computers in recent years. RESFEN 3.1 has the capability of analyzing the energy performance of windows in new residential buildings in 52 North American locations. The user describes the physical, thermal and optical properties of the windows in each orientation, solar heat gain reductions due to obstructions, overhangs, or shades, and the location of the house. The RESFEN program then models a prototypical house for that location and calculates the energy use of the house using the DOE-2 program. The user can vary the HVAC system, foundation type, and utility costs. Results are presented for the annual heating and cooling energy use, energy cost, and peak energy demand of the house, and the incremental energy use or peak demand attributable to the windows in each orientation. This paper describes the capabilities of RESFEN 3.1, its usefulness in analyzing the energy performance of residential windows and its development effort and gives insight into the structure of the computer program. It also discusses the rationale and benefits of the approach taken in RESFEN in combining a simple-to-use graphical front-end with a detailed hour-by-hour simulation engine to produce an energy analysis tool for the general public that is user-friendly yet highly accurate.

%B Thermal Performance of the Exterior Envelopes of Buildings VII %C Clearwater Beach, FL %8 12/1998 %G eng %L LBNL-42871 %1

Simulation Research Group

%2 LBNL-42871 %0 Conference Paper %B Building Simulation 99, International Building Performance Simulation Association (IBPSA) %D 1999 %T THERM 2.0: A Building Component Model for Steady-State Two-Dimensional Heat Transfer %A Charlie Huizenga %A Dariush K. Arasteh %A Elizabeth U. Finlayson %A Robin Mitchell %A Brent T. Griffith %A Dragan C. Curcija %X

THERM 2.0 is a state-of-the-art software program, available without cost, that uses the finite-element method to model steady-state, two-dimensional heat-transfer problems. It includes a powerful simulation engine combined with a simple, interactive interface and graphic results. Although it was developed primarily to model thermal properties of windows, it is appropriate for other building components such as walls, doors, roofs, and foundations, and is useful for modeling thermal bridges in many other contexts, such as the design of equipment.

%B Building Simulation 99, International Building Performance Simulation Association (IBPSA) %C Kyoto, Japan %8 09/1999 %G eng %L LBNL-43991 %1

Windows and Daylighting Group

%2 LBNL-43991 %0 Conference Paper %B ACEEE 1998 Summer Study on Energy Efficiency in Buildings %D 1998 %T State-of-the-Art Software for Window Energy-Efficiency Rating and Labeling %A Dariush K. Arasteh %A Elizabeth U. Finlayson %A Yu Joe Huang %A Charlie Huizenga %A Robin Mitchell %A Michael D. Rubin %X

Measuring the thermal performance of windows in typical residential buildings is an expensive proposition. Not only is laboratory testing expensive, but each window manufacturer typically offers hundreds of individual products, each of which has different thermal performance properties. With over a thousand window manufacturers nationally, a testing-based rating system would be prohibitively expensive to the industry and to consumers.

Beginning in the early 1990s, simulation software began to be used as part of a national program for rating window U-values. The rating program has since been expanded to include Solar Hear Gain Coefficients and is now being extended to annual energy performance.

This paper describes four software packages available to the public from Lawrence Berkeley National Laboratory (LBNL). These software packages are used to evaluate window thermal performance: RESFEN (for evaluating annual energy costs), WINDOW (for calculating a products thermal performance properties), THERM (a preprocessor for WINDOW that determines two-dimensional heat-transfer effects), and Optics (a preprocessor for WINDOWs glass database).

Software not only offers a less expensive means than testing to evaluate window performance, it can also be used during the design process to help manufacturers produce windows that will meet target specifications. In addition, software can show small improvements in window performance that might not be detected in actual testing because of large uncertainties in test procedures.

%B ACEEE 1998 Summer Study on Energy Efficiency in Buildings %C Pacific Grove, CA %8 08/1998 %G eng %L LBNL-42151 %1

Windows and Daylighting Group

%2 LBNL-42151 %0 Journal Article %J ASHRAE Transactions %D 1998 %T Teaching Students about Two-Dimensional Heat Transfer Effects in Buildings, Building Components, Equipment, and Appliances Using THERM 2.0 %A Charlie Huizenga %A Dariush K. Arasteh %A Elizabeth U. Finlayson %A Robin Mitchell %A Brent T. Griffith %X

THERM 2.0 is a state-of-the-art software program, available for free, that uses the finite-element method to model steady-state, two-dimensional heat-transfer effects. It is being used internationally in graduate and undergraduate laboratories and classes as an interactive educational tool to help students gain a better understanding of heat transfer. THERM offers students a powerful simulation engine combined with a simple, interactive interface and graphic results. Although it was developed to model thermal properties of building components such as windows, walls, doors, roofs, and foundations, it is useful for modeling thermal bridges in many other contexts, such as the design of equipment. These capabilities make THERM a useful teaching tool in classes on: heating, ventilation, and air-conditioning (HVAC); energy conservation; building design; and other subjects where heat-transfer theory and applications are important. THERMs state-of-the-art interface and graphic presentation allow students to see heat-transfer paths and to learn how changes in materials affect heat transfer. THERM is an excellent tool for helping students understand the practical application of heat-transfer theory.

%B ASHRAE Transactions %C Chicago, IL %V 105, Part 1 %8 01/1999 %G eng %L LBNL-42102 %1

Windows and Daylighting Group

%2 LBNL-42102 %0 Report %D 1998 %T THERM 2.0: a PC Program for Analyzing Two-Dimensional Heat Transfer through Building products %A Elizabeth U. Finlayson %A Robin Mitchell %A Dariush K. Arasteh %A Charlie Huizenga %A Dragan C. Curcija %X

THERM is a state-of-the-art, Microsoft Windows?-based computer program developed at Lawrence Berkeley National Laboratory (LBNL) for use by building component manufacturers, engineers, educators, students, architects, and others interested in heat transfer. Using THERM, you can model two-dimensional heat-transfer effects in building components such as windows, walls, foundations, roofs, and doors; appliances; and other products where thermal bridges are of concern. THERM's heat-transfer analysis allows you to evaluate a product?s energy efficiency and local temperature patterns, which may relate directly to problems with condensation, moisture damage, and structural integrity.

This version of THERM includes several new technical and user interface features; the most significant is a radiation view-factor algorithm. This feature increases the accuracy of calculations in situations where you are analyzing non-planar surfaces that have different temperatures and exchange energy through radiation heat transfer. This heat-transfer mechanism is important in greenhouse windows, hollow cavities, and some aluminum frames.

%G eng %L LBL-37371 Rev. 2 %1

Windows and Daylighting Group

%2 LBL-37371R %0 Journal Article %J ASHRAE Transactions %D 1997 %T Guidelines for Modeling Projecting Fenestration Products %A Dariush K. Arasteh %A Elizabeth U. Finlayson %A Dragan C. Curcija %A Jeff Baker %A Charlie Huizenga %X

Heat transfer patterns in projecting fenestration products (greenhouse windows, skylights, etc.) are different than those with typical planar window products. The projecting surfaces often radiate to each other, thereby invalidating the commonly used assumption that fenestration product interior surfaces radiate to a uniform room air temperature. The convective portion of the surface heat transfer coefficient is also significantly different from the one used with planar geometries, and is even more dependent on geometry and location. Projecting fenestration product profiles must therefore be modeled in their entirety. This paper presents the results of complete cross section, variable film-coefficient, 2-D heat transfer modeling of two greenhouse windows using the next generation of window specific heat transfer modeling tools. The use of variable film-coefficient models is shown to increase the accuracy with which simulation tools can compute U-factors. Simulated U-factors are also determined using conventional constant film coefficient algorithms. The results from both sets of simulations are compared with measured values.

%B ASHRAE Transactions %C San Francisco, CA %V 104, Part 1 %8 01/1998 %G eng %1

Windows and Daylighting Group

%2 LBNL-40707 %0 Report %D 1997 %T RESFEN 3.0: A PC Program for Calculating the Heating and Cooling Energy Use of Windows in Residential Buildings %A Yu Joe Huang %A Robert Sullivan %A Dariush K. Arasteh %A Robin Mitchell %X

Today's energy-efficient windows can dramatically lower the heating and cooling costs associated with windows while increasing occupant comfort and minimizing window surface condensation problems. However, consumers are often confused about how to pick the most efficient window for their residence. They are typically given window properties such as U-factors or R-values, Solar Heat Gain Coefficients or Shading Coefficients, and air leakage rates. However, the relative importance of these properties depends on the site and building specific conditions. Furthermore, these properties are based on static evaluation conditions that are very different from the real situation the window will be used in. Knowing the energy and associated cost implications of different windows will help consumers and builders make the best decision for their particular application, whether it is a new home, an addition, or a window replacement.

A computer tool such as RESFEN can help consumers and builders pick the most energy-efficient and cost-effective window for a given application. It calculates the heating and cooling energy use and associated costs as well as the peak heating and cooling demand for specific window products. Users define a problem by specifying the house type (single story or two story), geographic location, orientation, electricity and gas cost, and building configuration details (such as wall type, floor type, and HVAC systems). Window options are defined by specifying the window`s size, shading, and thermal properties: U-factor, Solar Heat Gain Coefficient, and air leakage rate. RESFEN calculates the energy and cost implications of the windows compared to insulated walls. The relative energy and cost impacts of two different windows can be compared against each other.

RESFEN 3.0 is a major improvement over previous versions of RESFEN because it performs hourly calculations using a version of the DOE 2.1E energy analysis simulation program.

%I Lawrence Berkeley National Laboratory %P 38 %8 12/1997 %2 LBNL-40682 %0 Conference Paper %B Thermal Performance of the Exterior Envelopes of Buildings VI Conference %D 1995 %T Advances in Thermal and Optical Simulations of Fenestration Systems: The Development of WINDOW 5 %A Elizabeth U. Finlayson %A Dariush K. Arasteh %A Michael D. Rubin %A John Sadlier %A Robert Sullivan %A Charlie Huizenga %A Dragan C. Curcija %A Mark Beall %X

WINDOW is a personal-computer-based computer program used by manufacturers, researchers, and consumers to evaluate the thermal performance properties (U-factors, solar heat gain and shading coefficients, and visible transmittances) of complete windows and other fenestration systems. While WINDOW is used by thousands of users in the United States and internationally and is at the foundation of the National Fenestration Rating Council's U-factor and solar heat gain property procedures, improvements to the program are still necessary for it to meet user needs. Version 5, intended for release in late 1995, is being developed to meet these needs for increased accuracy, a flexible and state-of-the-art user interface, and the capabilities to handle more product types.

WINDOW 5 includes the capabilities to define and model the thermal performance of frames/dividers and their associated edge effects. Currently, such an analysis must be performed outside of WINDOW and requires simplifications to be made to frame profiles or is based on the use of generic frame and edge correlations. WINDOW's two-dimensional thermal model is composed of four sections: a graphical input, automatic grid generation, an finite-element analysis (FEA) solution, and the display of results. In the graphical input section, users are able to directly import a computer-aided design (CAD) drawing or a scanned image of a window profile, replicate its exact geometry, and assign material types and boundary conditions. The automatic grid generation is transparent to the user, with the exception of the requirement that complex shapes (i.e., an aluminum extrusion) be broken down into simpler polyshapes. Inclusion of an automatic grid generation makes detailed "true geometry" frame-and-edge heat-transfer analysis accessible to users without extensive knowledge of numerical methods of heat-transfer analysis. After the cross section is meshed it is sent to the FEA engine for solution and the results are returned. A postprocessor allows for the visual display of temperature and heat flux plots. Note that while this two-dimensional heat-transfer tool is being developed specifically for fenestration products, it also can be used to analyze other building envelope components.

WINDOW 5 also will include a built-in version of a national laboratory's program that allows the user to estimate the orientation-dependent annual energy impacts of a given window in a typical residence in various U.S. climates. This program is based on regressions to a database of DOE2.1 runs. Future versions will include a similar feature for commercial buildings.

Other technical additions include an improved angular/ spectral model for coated and uncoated glazings, the ability to analyze the optical properties of nonhomogeneous layers, and the ability to model the effects of laminated glazing layers. A door module permits the user to compute the total U-factors of exterior doors based on component U-factors calculated using the two-dimensional FEA module.

%B Thermal Performance of the Exterior Envelopes of Buildings VI Conference %C Clearwater Beach, FL %8 12/1995 %G eng %1

Windows and Daylighting Group

%2 LBL-37283 %0 Conference Paper %B International Building Performance Simulation Association Fourth International Conference %D 1995 %T Advancing Lighting and Daylighting Simulation: The Transition from Analysis to Design Aid Tools %A Robert J. Hitchcock %X

This paper explores three significant software development requirements for making the transition from standalone lighting simulation/analysis tools to simulation-based design aid tools. These requirements include specialized lighting simulation engines, facilitated methods for creating detailed simulatable building descriptions, and automated techniques for providing lighting design guidance. Initial computer implementations meant to address each of these requirements are discussed to further elaborate these requirements and to illustrate work-in-progress toward fulfilling them.

%B International Building Performance Simulation Association Fourth International Conference %C Madison, WI %8 08/1995 %G eng %2 LBL-37285 %0 Conference Paper %D 1994 %T Characterization of Tantalum Oxide Films Prepared by Sol-Gel Process for electrochemical devices %A Nilgün Özer %A Yongxiang He %A Carl M Lampert %X

Tantalum oxide films were prepared by sol-gel process using tantalum ethoxide Ta(OC2H5)5. The dependence of deposition conditions (i.e. composition of polymeric solutions and spinning rate) on ionic conductivities for tantalum oxide films were studied. The best results achieved for films fabricated by the spin coating technique were from clear polymeric solutions. These films had low packing density ρ=3.2 g/cm3 and good proton conductivity (about 10-6 Ω-1 cm-1). X-ray photoelectron spectroscopy (XPS) was used for studying the compositions of the tantalum oxide films. We report on the use of tantalum oxide films as ion conductors in devices consisting of WO3/Ta2O5/H+ ion storage polymer structure. We found tantalum oxide to have very good properties for proton device applications.

%G eng %L LBNL-39005 %1

Windows and Daylighting Group

%2 LBNL-39005 %0 Journal Article %J ASHRAE Transactions %D 1994 %T Spectrally Selective Glazings for Residential Retrofits in Cooling-Dominated Climates %A Eleanor S. Lee %A Deborah Hopkins %A Michael D. Rubin %A Dariush K. Arasteh %A Stephen E. Selkowitz %K deserts %K domestic %K energy conservation %K Glazing %K housing %K modernising %K subtropics %K usa %K windows %X

Spectrally selective glazings can substantially reduce energy consumption and peak demand in residences by significantly reducing solar gains with minimal loss of illumination and view. In cooling-dominated climates, solar gains contribute 24–31% to electricity consumption and 40–43% to peak demand in homes with single pane clear glazing—standard practice for residential construction built before the implementation of building energy efficiency standards. The existing residential housing stock therefore offers a prime opportunity for significant demand-side management (DSM),but the energy and cost savings must be weighed against retrofit first costs in order for the technology to achieve full market penetration. Using DOE-2.1D for numerical simulation of building energy performance, we quantify the energy and peak demand reductions, cost savings, and HVAC capacity reductions using spectrally selective glazings for five cooling-dominated climates in California. The cost-effectiveness of various material and installation retrofit options is discussed. Glazing material improvements for retrofit applications that are needed to achieve a prescribed cost savings are also given.

%B ASHRAE Transactions %V 100 %G eng %N 1 %1

Windows and Daylighting Group

%2 LBL-34455 %! ASHRAE Trans. %0 Report %D 1994 %T WINDOW 4.1: Program Description %A Dariush K. Arasteh %A Elizabeth U. Finlayson %A Charlie Huizenga %X

WINDOW 4.1 is a publicly available IBM PC compatible computer program developed by the Windows and Daylighting Group at Lawrence Berkeley Laboratory for calculating total window thermal performance indices (i.e. U-values, solar heat gain coefficients, shading coefficients, and visible transmittances). WINDOW 4.1 provides a versatile heat transfer analysis method consistent with the rating procedure developed by the National Fenestration Rating Council (NFRC). The program can be used to design and develop new products, to rate and compare performance characteristics of all types of window products, to assist educators in teaching heat transfer through windows, and to help public officials in developing building energy codes.

WINDOW 4.1 is an update to WINDOW 4.0. The WINDOW 4 series is a major revision to previous versions of WINDOW. We strongly urge all users to read this manual before using the program. Users who need professional assistance with the WINDOW 4.1 program or other window performance simulation issues are encouraged to contact one or more of the NFRC-accredited Simulation Laboratories.

%G eng %L LBL-35298 %1

Windows and Daylighting Group

%2 LBL-35298 %0 Conference Paper %B SPIE Proceedings 2017 %D 1993 %T Characteristics of Laminated Electrochromic Devices Using Polyorganodisulfate Electrodes %A Carl M Lampert %A Steven J. Visco %A Marca M. Doeff %A Yan Ping Ma %A Yongxiang He %A Jean-Christophe Giron %X

The use of polyorganodisulfides as optically passive counterelectrodes in a variety of electrochromic devices are discussed. Characteristic data is presented for electrochmmic devices using proton, and lithium coloration ions with polyethylene oxide electrolyte and polydimercaptothiadiazole positive electrodes. Solid state devices consisting of molybdenum doped W03, amorphous polyethylene oxide electrolyte (a-PEO), and a polyorganodisulfide counter-electrode colored rapidly from a pale yellow to a deep blue-green, upon application of 1.2 V d.c. The photopic transmittance changed from 61 to 98, and the solar transmittance from 45 to 5% during the coloration process. Also, our experiments with polyimidazole are detailed. This family of compounds due to its unique electrical and ion conduction properties allow a single composite ion storage and ion conductor electrode to be made, simplifying the device construction. Devices rnade from this family of compounds color to deep blue-gray upon application of 1.2-1.5 V. Bleaching occurs at -0.4 to -0.5 s. The photopic transmittance changed from 55 to 9%. and the solar transmittance from 34 to 4% during coloration. Both coloration and bleaching are quite rapid.

%B SPIE Proceedings 2017 %P 143 %G eng %L LBL-33144 %1

Windows and Daylighting Group

%2 LBL-33144 %0 Report %D 1993 %T Window 4.0: Documentation of Calculation Procedures %A Elizabeth U. Finlayson %A Dariush K. Arasteh %A Charlie Huizenga %A Michael D. Rubin %A M. Susan Reilly %X

WINDOW 4.0 is a publicly available IBM PC compatible computer program developed by the Building Technologies Group at the Lawrence Berkeley Laboratory for calculating the thermal and optical properties necessary for heat transfer analyses of fenestration products. This report explains the calculation methods used in WINDOW 4.0 and is meant as a tool for those interested in understanding the procedures contained in WINDOW 4.0. All the calculations are discussed in the International System of units (SI).

%G eng %L LBL-33943 %1

Windows and Daylighting Group

%2 LBL-33943